Usb firewall apparatus and method

ABSTRACT

Apparatus and methods prevent malicious data in Universal Serial Bus (USB) configurations by providing a hardware firewall. A hardware device interconnected between a host and the USB monitors communication packets and blocks packets having unwanted or malicious intent. The device may act as a hub, enabling multiple devices to connect to a single host. The device may only allow mass storage packets from a device recognized as a mass storage device. The device may block enumeration of unwanted devices by not forwarding packets between the device and the host. The device may be operative to assign a bogus address to a malicious device so as not to transfer communications from the device further up the chain to the host. The device may provide shallow or deep packet inspection to determine when a trusted device is sending possible malicious data, or provide packet validation to block packets that are malformed.

REFERENCE TO RELATED APPLICATION

This application claims priority from U.S. Provisional Patent Application Ser. No. 61/453,777, filed Mar. 17, 2011, the entire content of which is incorporated herein by reference.

FIELD OF THE INVENTION

This invention relates generally to computer security and, in particular, to apparatus and methods that prevent malicious data in Universal Serial Bus (USB) configurations by providing a hardware firewall.

BACKGROUND OF THE INVENTION

The Universal Serial Bus (USB) is a common interconnect format for computer devices. Data is transmitted over a serial connection between a host and a device. Each device is assigned an address form 0-127, allowing multiple devices to communicate with the same host using the same wires.

The USB specification allows multiple device classes, including but not limited to keyboards, mice, printers, mass storage, video, and vendor specific items. Some physical devices appear as two or more logical USB devices, such as a webcam that has an audio and a video USB connection. USB data is sent in packets, some of which signal devices being added or removed. Other packet types are data, signaling such as acknowledgement of data received or ready, and other types.

Malicious USB devices have been created that utilize weaknesses in the USB infrastructure to attack unprotected hosts and devices through combinations of malformed packets, device spoofing, electrical tricks, and other methods. For example, a flash drive may have a keyboard controller hidden in it that only activates after the drive has been inserted for some length of time. The keyboard activates, unsuspecting USB infrastructure connects it to the PC, and the keyboard sends commands for malicious activity on the host PC. There are many other types of attacks.

SUMMARY OF THE INVENTION

This invention is directed to apparatus and methods that prevent malicious data in Universal Serial Bus (USB) configurations by providing a hardware firewall. A computer security device according to the invention comprises a hardware unit interconnected between a Universal Serial Bus (USB) device and a host. The device, which may include a memory to log data exchanges, monitors communication packets associated with data exchanges between the bus and the host and blocks packets having unwanted or malicious intent.

In some embodiments, the device may only allow mass storage packets from a device recognized as a mass storage device. The device may block enumeration of unwanted devices by not forwarding packets between the device and the host. The device may be operative to assign a bogus address to a malicious device so as not to transfer communications from the device further up the chain to the host. The device may provide shallow or deep packet inspection to determine when a trusted device is sending possible malicious data, or provide packet validation to block packets that are malformed.

In the preferred embodiment, the device acts as a hub, enabling multiple devices to connect to a single host. The device may interface to the host through a first USB connector, and interface to the USB through a second USB connector. For added security, the device may be interfaced to the host through an optically isolated bus. Methods of use are also disclosed and claimed herein.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a USB firewall device constructed in accordance with the present invention; and

FIG. 2 illustrates transfer between the device and a host, which are broken into transactions, and which are further broken into packets.

DETAILED DESCRIPTION OF THE INVENTION

This invention prevents malicious data in USB configurations by providing a hardware firewall. All USB data is sent between a device and a host. The firewall sites physically between them, either acting as a hub (which connects multiple devices to a single host) or acting passively by sitting on the wire to listen to traffic. In the latter case it does not change traffic but nevertheless monitors and logs data.

The firewall, depicted schematically in FIG. 1 includes a hardware monitor that sits between two communicating USB endpoints and monitors USB data. The device stops communication packets it deems are not wanted by the user or that have malicious intent. For example, a user could set the hardware to only allow mass storage packets from a device that should only be mass storage.

The firewall can stop malicious device types by monitoring the USB pipes (connections between device and host) and watching for new connection enumeration. When a new device tries to connect to the system, the host enumerates the device by first noticing changes on the bus, then performing transfers that obtain the device information. The device responds to the host through a specified endpoint which the device can monitor.

The firewall can block enumeration of devices that are not allowed to pass the firewall by not forwarding packets between the device to the host. The firewall assigns an address to the malicious device and makes the device think it was on a valid host, but would not transfer the communication further up the chain to the host.

Interactions between device and host are carried out through transfers, which are broken into transactions, which are further broken into packets (FIG. 2). Each packet has components detailing which device the packet refers to. Using this addressing, the firewall could assign addresses to devices it wants to block and other addresses to devices that are cleared to pass through, and the firewall would sort communication based on device address. This allows filtering communication by device on the untrusted side of the firewall.

For packets that are allowed through, the device provides shallow or deep packet inspection to determine when a trusted device is sending possible malicious data. One example would be to detect file transfers from mass storage devices and examine the files as they pass through. Another example detects images coming from a camera and scans the image headers for valid parameters.

This device can also provide a level of validation on the packets to ensure they are not malformed. Malformed packets can be designed to exploit weaknesses or errors in USB implementations, such as buffer overflows. For example, checking that fields in packets are correctly formed gives a second layer of protection against poorly implemented hardware that may be susceptible to invalid fields or invalid combinations of fields.

This device can electrically isolate the two connections to prevent electrical attacks, for example by using an optically isolated bus. 

1. A computer security device, comprising: a hardware unit interconnected between a Universal Serial Bus (USB) device and a host, the unit including a bus controller interfaced to a memory; and wherein the controller is operative to: (a) monitor communication packets associated with data exchanges between the bus and the host, (b) log the data exchanges in the memory, and (c) block communication packets unwanted or malicious intent from reaching the host.
 2. The computer security device of claim 1, wherein the unit only allows mass storage packets from a device recognized as a mass storage device.
 3. The computer security device of claim 1, wherein the unit blocks enumeration of unwanted devices by not forwarding packets between the device and the host.
 4. The computer security device of claim 1, wherein the unit is operative to assign a bogus address to a malicious device so as not to transfer communications from the device further up the chain to the host.
 5. The computer security device of claim 1, wherein the unit provides shallow or deep packet inspection to determine when a trusted device is sending possible malicious data.
 6. The computer security device of claim 1, wherein the unit further provides packet validation to block packets that are malformed.
 7. The computer security device of claim 1, wherein the unit is interfaced to the host through an optically isolated bus.
 8. The device of claim 1, wherein the unit acts as a hub enabling multiple devices to connect to a single host.
 9. The device of claim 1, wherein: the unit interfaces to the host through a first USB connector; and the unit interfaces to the USB through a second USB connector.
 10. A method protecting a computer from network attacks, comprising the steps of: monitoring and logging communication packets associated with data exchanges between a host and a Universal Serial Bus (USB) to which the host is connected; determining if the communication packets are unwanted or have malicious intent; and, if so: blocking those packets from reaching the host.
 11. The method of claim 10, including the step of allowing mass storage packets from a device recognized as a mass storage device.
 12. The method of claim 10, including the enumeration of unwanted devices by not forwarding packets between the device and the host.
 13. The method of claim 10, including the step of assigning a bogus address to a malicious device so as not to transfer communications from the device further up the chain to the host.
 14. The method of claim 10, including the step of providing shallow or deep packet inspection to determine when a trusted device is sending possible malicious data.
 15. The method of claim 10, including the step of providing packet validation to block packets that are malformed. 